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This study reports on “phase” transitions of Xe condensates in on‐surface confinements induced by temperature changes and local probe excitation. The pores of a metal‐organic network occupied with 1 up to 9 Xe atoms are investigated in their propensity to undergo “condensed solid” to “confined fluid” transitions. Different transition temperatures are identified, which depend on the number of Xe atoms...
A 2D array of electronically coupled quantum boxes is fabricated by means of on‐surface self‐assembly assuring ultimate precision of each box. The quantum states embedded in the boxes are configured by adsorbates, whose occupancy is controlled with atomic precision. The electronic interbox coupling can be maintained or significantly reduced by proper arrangement of empty and filled boxes.
A quantum breadboard is presented on page 3757 by S. Nowakowska, L. H. Gade, J. Lobo‐Checa, T. A. Jung, and co‐workers, composed of a 2D metalorganic network creating surface state derived quantum well states in the pores. Scanning probe microscopy manipulation of Xe atoms is used to configure the Xe population of the pores, which affects the quantum state of the 2D array or breadboard.
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